Process of producing viscose rayon



States PROCESS OF PRODUCING VISCOSE RAYUN No Drawing. Original application November 3, 1954, Serial No. 466,680. Divided and this application January 2, 1958, Serial No. 706,875

6 Claims. (Cl. 106-465) This invention relates to the production of shaped bodies of regenerated cellulose from viscose and more particularly to filaments and fibers of regenerated cellulose from viscose.

In the conventional methods of producing shaped bodies of regenerated cellulose from viscose, a suitable cellulosic material such as purified cotton linters, wood pulp, mixtures thereof, and the like is first converted to an alkali cellulose by treatment with a caustic soda so lution and after shredding the treated cellulose material, it is allowed to age. The aged alkali cellulose is then converted to a xanthate by treatment with carbon disulfide. The cellulose xanthate is subsequently dissolved in a caustic soda solution in an amount calculated to provide a viscose of the desired cellulose and alkali content. After filtration, the viscose solution is allowed to ripen and is subsequently extruded through a shaped orifice into a suitable coagulating and regenerating bath.

In the production of shaped bodies such as filaments, the viscose solution is extruded through a spinneret into a coagulating and regenerating bath consisting of an aqueous acid solution containing zinc sulfate. The filament may subsequently be passed through a hot aqueous bath where it is stretched to improve its properties such as tensile strength. The filament may then be passed through a dilute aqueous solution of sulfuric acid and sodium sulfate to complete the regeneration of the cellulose, in case it is not completely regenerated upon leaving the stretching stage. The filament is subsequently subjected to washing, purification, bleaching, possibly other treating operations and drying, being collected either before or after these treatments.

The filaments as formed by the conventional methods, consist of a skin or outer shell portion and a core portion with a sharp line of demarkation between the two. The cross-section of the filaments exhibits a very irregular or crenulated exterior surface when even small amounts of zinc salts or certain other polyvalent metal salts are present in the spinning bath. The skin and core portions of the filament represent difierences in structure and these different portions possess different swelling and staining characteristics, the latter permitting a ready identification of skin and core. The sharply irregular and crenulated surface structure has a relatively low abrasion resistance and readily picks up foreign particles such as dirt. Although the core portion possesses a relatively high tensile strength, it has a low abrasion resistance and a low flex-life, is subjected to fibrillation and is relatively stiff.

It has now been discovered that the presence of small amounts of alkali-soluble alkylene oxide adducts of certain amino fatty alkyl amides in a viscose which has a relatively high salt test results in the production of shaped bodies of regenerated cellulose such as filaments, films, sheets, and the like composed of all skin and having improved properties and characteristics providing that the amount of the adduct is maintained with certain limits and the composition of the spinning bath is mainatent 2,916,391 Patented Dec. 8, 1959 n-l wherein 0 ll RC is a fatty alkoyl radical of fatty acids and/or esters of fatty acids found in naturally occurring fats and oils such as sperm oil, cottonseed oil, coconut oil, corn oil, soya bean oil, palm oils, peanut oil and the like and the hydrogenated fats and oils. These acids and esters are straight chain saturated or unsaturated aliphatic compounds having from 8 to 24 carbon atoms in the 0 ll R-C group. Fatty acids and/or esters of fatty acids having from 12 to 18 carbon atoms in the group are preferred as the predominant base materials for preparing the amino amides.

With respect to the remaining part of the above formula, i.e., exclusive of the 0 II RC group, n is an integer from 1 to 10. A number of ethylene or polyethylene polyamino groups are thus encompassed by the formula, but it is to be understood that other alkyl polyamino groups such as the propylene polyamino groups are also operative.

Compounds described by the above formula, therefore, are most conveniently prepared by reacting a naturally occurring fat or oil directly with a polyamine. For example, sperm oil which contains chiefly esters of oleic and palmitic acids and dodecyl and cetyl alcohols, was reacted with ethylene diamine to produce a mixture comprising N-(B-amino ethyl) oleamide and N-(B-amino ethyl) palmitamide.

Various alkylene oxides such as ethylene oxide and propylene oxide may be condensed with the amino fatty alkyl amides defined above to form the polyoxyalkylene compounds contemplated in this invention. It is obvious, however, that for all practical purposes, considering cost, ease of preparation, commercial availability and solubility in water, and alkaline solutions such as a 6% caustic solution, the ethylene oxide adducts are preferred. Accordingly, the invention will be illustrated specifically by reference to the ethylene oxide adducts.

The structural formula for the ethylene oxide adducts is as follows:

R-t iNH. oH2l:oH21 IoH2 2 l )1/ wherein 0 ll RC is the fatty alkoyl radical defined in the foregoing formula for the amino amide, n is an integer from 1 to 10 as also defined above and x plus y is from to 30. It is preferred that x plus y, i.e., the number of moles of ethylene oxide per mole of the amide, is from 12 to 20 so that the adduct is economical to produce and readily soluble in alkaline solutions. The adducts must have a minimum alkali-solubility (the solubility being increased as more ethylene oxide is condensed with the amide) which is sufficient to dissolve the required amount of adduct in viscose. It is probable, but not necessary, that the condensation will effect an equal distribution of ethylene oxide units on each of the two nitrogen bonds between the amino and polyoxyethylene groups. Other hydrogen atoms linked to the nitrogen atoms, including the amide nitrogen, in the amino amide may also be replaced by polyoxyethylene groups in the course of the condensation reaction but the terminal nitrogen atom is definitely more reactive with respect to the addition of ethylene oxide.

The amount of the adduct which is incorporated in the viscose must be at least about 0.2% by weight of the cellulose and may vary up to about 4%, preferably, the amount varies from about 0.5% to 2.5%. Lesser amounts do not result in the production of products consisting entirely of skin and greater amounts affect adversely the physical properties of the products. Amounts within the preferred range are most effective in enhancing the characteristics and properties of the products. The adduct may be added at any desired stage in the production of the viscose, preferably being added after the cellulose xanthate has been dissolved in the caustic solution.

The composition of the viscose proper to the incorporation of the adduct is, in general, conventional in the art. The viscose may contain from about 4% to about 8% cellulose, the particular source of the cellulose being selected for the ultimate use of the regenerated cellulose product. The caustic sode content may be from about 4% to about 8% and the carbon disulfide content may be from about 30% to about 50% based upon the weight of the cellulose.

The modified viscose of this invention, i.e., a viscose containing a small amount of the alkylene oxide adduct, has a salt test above about 6 and preferably above 8 at the time of spinning or extrusion.

In order to obtain the improvements enumerated here inbefore it is essential that the composition of the spinning bath be maintained within a well defined range. When the modified viscose described above is extruded into the limited spinning baths defined below, yarns of improved properties such as high tenacity, high abrasion resistance, high fatigue resistance and consisting of filaments composed entirely of skin are produced.

Generically and in terms of the industrial art, the spinning bath is a low acid-high zinc spinning bath. The bath should contain from about about 10% to about 25% sodium sulfate and from about 3% to about zinc sulfate, preferably from 15 to 22% sodium sulfate and from 4% to 9% zine sulfate. Other metal sulfates such as iron, manganese, nickel and the like may be present and may replace some of the zinc sulfate. The temperature of the spinning bath may vary from about 25 C. to about 80 0., preferably between about 45 C. to about 70 C. In the production of the all skin type filaments, the temperature of the spinning bath is not critical, however, as is well known in the conventional practice in the art, certain of the physical properties such as tensile strength vary directly with the temperature of the spinning bath. Thus, in the production of filaments for tire cord purposes in accordance with the method of this invention, the spinning bath is preferably maintained at a temperature between about 55 C. and 65 C. so as to obtain the desired high tensile strength.

The acid content of the spinning bath is balanced against the composition of the viscose. The lower limit of the acid concentration, as is well known in the art, is just above the slubbing point, that is, the concentration at which small slubs of uncoagulated viscose appear in the strand as it leaves the spinning bath. For commercial operations, the acid concentration is generally maintained about 0.4% to 0.5% above the slubbing point. For any specific viscose composition, the acid concentration of the spinning bath must be maintained above the slubbing point and below the concentration at which the neutralization of the caustic of the viscose is sufficiently rapid to form a filament having a skin and core.

There is a maximum acid concentration for any specific viscose composition beyond which the neutralization is sufiiciently rapid to produce filaments having a skin and core. For example, in general, the acid concentration of the spinning baths which are satisfactory for the commercial production of the all skin products from a 7% cellulose, 6% caustic viscose containing adducts of the amino amides lies between about 5% and about 8%. The acid concentration may be increased as the amount of additive or modifier is increased and also as the salt test of the viscose is increased. There is an upper limit, however, for the acid concentration based upon the amount of modifier and the concentration of caustic in the viscose. All skin products cannot be obtained if the acid content of the bath is increased above the maximum value although the amount of the modifier is increased beyond about 6% while other conditions are maintained constant. Increasing the caustic content of the viscose beyond about 8% is uneconomical for commercial production methods. For example, a viscose containing about 7% cellulose, about 6% caustic soda, about 41% carbon disulfide and 1% of an ethylene oxide adduct of N-(B-amino ethyl) oleamide having about 14 ethylene oxide units per molecule and the viscose having a salt test of 9 to 10 when extruded into spinning baths containing 16 to 20% sodium sulfate, 4 to 8% zinc sulfate and sulfuric acid not more than about 7.5%, results in the production of all skin filaments. Lesser amounts of sulfuric acid may be employed. Greater amounts of acid result in the production of products having skin and core. It has been determined that the maximum permissible acid content of the bath is approximately 1.30 times the caustic content of the viscose and is preferably maintained between about 1.15 and 1.25 times the caustic content. A lowering of the amount of modifier, the lowering of the caustic soda content or the lowering of the salt test of the viscose reduces the maximum permissible acid concentration for the production of all skin filaments.

The presence of the ethylene oxide adducts of the amino amides in the viscose retards the coagulation and, therefore, the amount of the ether employed must be reduced at high spinning speeds. Thus, for optimum physical characteristics of an all skin yarn formed from a viscose as above and at a spinning speed of about 50 meters per minute, the ether is employed in amounts within the lower portion of the range, for example, about 0.5 The determination of the specific maximum and optimum concentration of acid for any specific viscose, spinning bath and spinning speed is a matter of simple experimentation for those skilled in the art. The extruded viscose must, of course, be immersed or maintained in the spinning bath for a period sufiicient to effect relatively complete coagulation of the viscose, that is, the coagulation must be sufficient so that the filaments will not adhere to each other as they are brought together and withdrawn from the bath.

In the production of filaments for such purposes as the fabrication of tire cord, the filaments are preferably stretched after removal from the initial coagulating and regenerating bath. From the initial spinning bath, the filaments may be passed through a hot aqueous bath which may consist of hot water or a dilute acid solution and may be stretched from about 70% to about 110%, preferably between and Yarns for other textile purposes may be stretched as low as 20%. The precise amount of stretching will be dependent upon the desired tenacity and other properties and the specific type of product being produced. It is to be understood that the invention is not restricted to the production of filaments and yarns but it is also applicable to other shaped bodies such as sheets, films, tubes and the like. The filaments may then be passed through a final regenerating bath which may contain from about 1% to about 5% sulfuric acid and from about 1% to about 5% sodium sulfate with or without small amounts of zinc sulfate if regeneration has not previously been completed.

The treatment following the final regenerating bath, or the stretching operation where regeneration has been completed, may consist of a washing step, a desulfurizing step, the application of a finishing or plasticizing material and drying before or after collecting, or may include other desired and conventional steps such as bleaching and the like. The treatment after regeneration will be dictated by the specific type of shaped body and the proposed use thereof.

Regenerated cellulose filaments prepared from viscose containing the small amounts of the adducts described herein and spun in the spinning baths of limited acid content have a smooth or non-crenulated surface and consist substantially entirely of skin. Because of the uniformity of structure throughout the filament, the swelling and staining characteristics are uniform throughout the crosssection of the filament. Filaments produced pursuant to this invention and consisting entirely of skin have a high toughness and a greater flexing life than filaments as produced according to prior methods which may be attributed by the uniformity in skin structure through the filament. Although the twisting of conventional filaments, as in the production of tire cord results in an appreciable loss of tensile strength, there is appreciably less loss in tensile strength in the production of twisted cords from the filaments consisting entirely of skin. Filaments prepared from viscose containing the adducts have a high tensile strength as compared to normal regenerated cellulose filaments, have superior abrasion and fatigue resistance characteristics and have a high fiex-life. Such filaments are highly satisfactory for the production of cords for the reinforcement of rubber products such as pneumatic tire casings, but the filaments are not restricted to such uses and may be used for other textile applications.

The invention may be illustrated by referenceto the preparation of regenerated cellulose filaments from a viscose containing about 7% cellulose, about 6% caustic soda, and having a total carbon disulfide content of about 41% based on the weight of the cellulose. The viscose solutions were prepared by xanthating alkali cellulose by the introduction of 36% carbon disulfide, based on the weight of the cellulose and churning for about 2 /2 hours. The cellulose xanthate was then dissolved in caustic soda solution. An additional 5% carbon disulfide was then added to the mixer and the mass mixed for about one hour. The ethylene oxide adduct of the amino amide was added to the caustic soda solution and mixed for about one-half hour. The adduct employed in the following examples was prepared by condensing ethylene oxide with an amino amide which in turn was prepared by reacting sperm oil with ethylene diamine. About 14 moles of ethylene oxide per mole of the amino amide were used in the condensation reaction. As set forth ereinabove, the amino amide derived from sperm oil is essentially a mixture comprising N-(B-amino ethyl) oleamide and N-(B-amino ethyl) palmitamide. The percentages stated in the examples below are by weight.

Example 1 Approximately 2% of the adduct defined above, containing about 14 ethylene oxide units per molecule was added to and incorporated in the viscose as described above. The viscose employed in the Spinning of filaments had a salt test of 9.0. The viscose was extruded through a spinnerette to form a 1640 denier, 720 filament yarn at a rate of about 22 meters per minute. The coagulating and regenerating bath was maintained at a temperature of about 60 C. and contained 7.3% sulfuric acid, 8% zinc sulfate and 17% sodium sulfate. The yarn was passed over a godet from which it was conducted through a hot water bath maintained at about 90 C. During the travel through the hot water bath, the yarn was stretched approximately 90%. The yarn was then collected in a spinning box, washed free of acid and salts and dried.

The individual filaments formed from viscose containing the adduct had a smooth, non-crenulated exterior surface and consisted entirely of skin, no core being detectable at high magnification (e.g. l500 The yarn had a dry tensile strength of 4.50 gms. per denier and a wet tensile strength of 3.21 gms. per denier. The elongation at breaking was 12.6% dry and 27.3% wet.

Example 2 stretched about 90%, washed free of acid and salts by.

treatment with water at about 90 C. on thread-advancing reels, dried and collected on a cone.

The individual filaments were smooth, non-crenulated and consisted entirely of skin. The yarn had a dry tensile strength of 4.42 gms. per denier and a wet tensile strength of 3.23 gms. per denier. The elongation at breaking was 11.6% dry and 28.3% wet.

Example 3 Approximately 1% of the adduct used in Examples 1 and 2 was added to and incorporated in viscose as described above. The viscose employed in the spinning of filaments had a salt test of 9.8. The viscose was extruded through a spinnerette to form a 1640 denier, 720 filament yarn at a rate of about 21 meters per minute. The coagulating and regenerating bath was maintained at a temperature of about 60 C. and contained 7.0% sulfuric acid, 8.0% Zinc sulfate and 17% sodium sulfate. The yarn was stretched about 90%, washed free of acid and salts by treatment with water at about 90 C. on threadadvancing reels, dried and collected on a cone.

The individual filaments formed from viscose containing the adduct had a smooth, non-crenulated exterior surface and consisted entirely of skin. The yarn had a dry tensile strength of 4.47 gms. per denier and a wet tensile strength of 3.05 gms. per denier. The elongation at breaking was 12.7% dry and 25.3% wet.

In each of the above examples, control yarns were spun from viscose containing no additives but into the same controlled baths. The individual filaments of the control yarns had very irregular and serrated surfaces and consisted of from about 50 to skin and from about 20 to 50% core with a sharp line of demarkation between skin and core.

One of the properties of viscose rayon which has limited its uses is its relatively high cross-sectional swelling when wet with water, this swelling amounting to from about 65% to about 80% for rayon produced by conventional methods. Rayon filaments produced in accordance with the method of this invention have an appreciably lower cross-sectional swelling characteristic, the swelling amounting to from about 45% to about 60%.

If desired, small amounts of the adducts may be added to the spinning bath. Since the substances are also watersoluble, some of the modifier will be leached from the filament and will be present in the bath.

The modifier of this invention may be added to any desired viscose such as those normally used in industry, the specific viscose composition set forth above, being merely for illustrative purposes. The adducts may be added at any desired stage in the production of the viscose and may be present in the cellulosic raw material provided that the amount present will produce a viscose having the proper proportion of the ether at the time of spinning.

The term skin is employed to designate that portion of regenerated cellulose filaments which is permanently stained or dyed by the following procedure: A microtome section of one or more of the filaments mounted in a wax block is taken and mounted on a slide with Meyers albumin fixative. After dewaxing in xylene, the section is placed in successive baths of 60% and 30% alcohol for a few moments each, and it is then stained in 2% aqueous solution of Victoria Blue BS conc. (General Dyestuffs Corp.) for 1 to 2 hours. At this point, the entire section is blue. By rinsing the section first in distilled water and then in one or more baths composed of 10% water and 90% dioxane for a period varying from 5 to 30 minutes depending on the particular filament, the dye is entirely removed from the core, leaving it restricted to the skin areas.

This application is a division of our copending application Serial No. 466,680, filed November 3, 1954.

While preferred embodiments of the invention have been disclosed, the description is intended to be illustrative and it is to be understood that changes and variations may be made without departing from the spirit and scope of the invention as defined by the appended claims.

We claim:

1. A viscose spinning solution containing from about 0.2% to 4%, based on the weight of the cellulose in the viscose, of an alkali-soluble alkylene oxide adduct of a substance selected from the compounds and mixtures of compounds having the following structural formula wherein is a straight chain acyl radical containing 8 to 24 carbon atoms and n is an integer from 1 to 10, the adduct having from 10 to 30 alkylene oxide units per molecule, the alkylene oxide being selected from the group consisting of ethylene oxide and propylene oxide.

2. A viscose spinning solution as defined in claim 1 wherein the viscose contains from about 0.2% to 4%, based on the weight of the cellulose in the viscose, of an alkylene oxide adduct as defined in claim 1 wherein the adduct is an ethylene oxide adduct.

3. A viscose spinning solution as defined in claim 1 wherein the viscose contains from about 0.2% to 4%, based on the weight of the cellulose in the viscose, of an alkylene oxide adduct of a mixture of N-(B-amino ethyl) oleamide and N-(B-aniino ethyl) palmitamide, the

alkylene oxide being selected from the group consisting of ethylene oxide and propylene oxide, the adducts containing from 10 to 30 alkylene oxides per molecule.

4. A cellulosic raw material for the preparation of viscose containing from about 0.2% to 4%, based on the weight of the cellulose, of an alkali-soluble alkylene oxide adduct of a substance selected from the compounds and mixtures of compounds having the following structural formula is a straight chain acyl radical containing 8 to 24 carbon atoms and n is an integer from 1 to 10, the adduct having from 10 to 30 alkylene oxide units per molecule, the alkylene oxide being selected from the group consisting of ethylene oxide and propylene oxide.

5. A cellulosic raw material as defined in claim 4 wherein the cellulosic raw material contains from about 0.2% to 4%, based on the weight of the cellulose, of an alkylene oxide adduct as defined in claim 4 wherein the adduct is an ethylene oxide adduct.

6. A viscose spinning solution containing a small amount of an alkali-soluble alkylene oxide adduct of a substance selected from the compounds and mixtures of compounds having the following structural formula is a straight chain acyl radical containing 8 to 24 carbon atoms and n is an integer from 1 to 10, the adduct containing from 10 to 30 alkylene oxide units per molecule, the alkylene oxide being selected from the group consisting of ethylene oxide and propylene oxide, said small amount of the adduct being a quantity sufficient to impart a smooth, non-crenulated surface and a substantially all skin structure to products formed by spinning the viscose at a sodium chloride salt test of at least 6 into an aqueous bath containing from 15% to 22% sodium sulfate, from 4% to 9% zinc sulfate and sulfuric acid in a percentage of between 1.15 and 1.25 times the percentage of caustic soda in the viscose, but the quantity being insuificient to adversely affect the physical properties of such products.

References Cited in the file of this patent UNITED STATES PATENTS 2,535,044 Cox Dec. 26, 1950 2,572,217 Thurmond Oct. 23, 1951 2,664,360 Charles et al. Dec. 29, 1953 2,710,861 Charles et al. June 14, 1955 LLJM. 

1. A VISCOSE SPINNING SOLUTION CONTAINING FROM ABOUT 0.2% TO 4%, BASED ON THE WEIGHT OF THE CELLULOSE IN THE VISCOSE, OF AN ALKALI-SOLUBLE OXIDE ADDUCT OF A SUBSTANCE SELECTED FROM THE COMPOUNDS AND MIXTURES OF COMPOUNDS HAVING THE FOLLOWING STRUCTURAL FORMULA 